Observation and analysis of diving beetle movements while swimming

Qi, Debo; Zhang, Chengchun; He, Jingwei; Yue, Yongli; Wang, Jing; Xiao, Dunhui

doi:10.1038/s41598-021-96158-1

Cited by 7 publications

(1 citation statement)

References 42 publications

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“…Aquatic creatures, like fishes and sea mammals, have developed remarkable underwater cruising and maneuvering skills, such as high swimming speed and small turning radius. [ 66 ] In particular, body and caudal fin (BCF) movements, including tailbeats, have been of essence to understand the propulsion mechanisms and turning activities of the fish. [ 67 ] The current analytic approach, involving an invasive implantation procedure, unfortunately causes injuries to the object and the rigid structure of the sensor may adversely restrict body motions.…”

Section: Applicationsmentioning

confidence: 99%

Aquatic Skin Enabled by Multi‐Modality Iontronic Sensing

Cheng

Guo

et al. 2022

Adv Funct Materials

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Perception of information is of critical importance for aquatic activities; however, the complex underwater situation faces unique technical challenges to address. Thus, an underwater environment-incorporated sensing strategy, referred to as aquatic skin, has been introduced with multi-modality sensing capacities of contact pressure, tactile mapping, depth, temperature, and salinity in a flexible architecture. Remarkably, this has been all achieved by a multi-modality iontronic sensing principle in an all-in-one structural configuration, simplifying the sensor design, material preparation, device fabrication, and signal processing. Particularly, an inverse iontronic sensing mechanism, utilizing complementary elastomeric-electrode and environmental-electrode interfaces, is developed for contact pressure detection with exceptional resolution and hydraulic balance. Moreover, a hydrophobic ionic gel with adjustable surface morphologies has been developed as the functional sensing layer for all the units with long-term stability. Consequently, the aquatic skin can achieve sub-Pascal resolution of contact pressure detection (0.59 Pa), and sub-millimeter spatial resolution of tactile mapping (522 pts cm −2 ) over an extended range of depths (0-40 m), while the environmental influences can be spontaneously eliminated through a self-compensation process. The aquatic skin is applied toward several representative underwater scenes, including real-time monitoring of vital/environmental signals, tactile recognition of creatures, and biomechanical analysis of fish swimming.

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Section: Applicationsmentioning

confidence: 99%

Aquatic Skin Enabled by Multi‐Modality Iontronic Sensing

Cheng

Guo

et al. 2022

Adv Funct Materials

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Multi‐Level Structural Enhancement Mechanism of the Excellent Mechanical Properties of Dung Beetle Leg Joint

Tuo,

Yang,

et al. 2024

Small

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The multi‐level structure is a strategy to enhance the mechanical properties of dung beetle leg joints. Under external loads, the microstructure facilitates energy dissipation and prevents crack extension. The macrostructure aids in transferring the load to more reliable parts. The connection established by the two hemispheres is present in the dung beetle leg joint. The micron‐layered and nanoscale crystal structures further constitute the leg joint with excellent mechanical properties. The maximum compression fracture force is ≈101000 times the weight of the leg. Here, the structural design within the dung beetle leg joints and reveal the resulting mechanical response and enhancement mechanisms is determined. A series of beetle leg joints where the macrostructure and microstructure of the dung beetle leg provide mechanical strength at critical strains while avoiding catastrophic failure by transferring the load from the joint to the exoskeleton of the femur is highlighted. Nanocrystalline structures and fiber layers contribute to crack propagation of the exoskeleton. Based on this, the bionic joint with multi‐level structures using resin and conducted a series of tests to verify their effectiveness is prepared. This study provides a new idea for designing and optimizing high‐load joints in engineering.

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